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mRNA is a new class of drugs that has the potential to revolutionize the treatment of brain tumors. Thanks to the COVID-19 mRNA vaccines and numerous therapy-based clinical trials, it is now clear that lipid nanoparticles (LNPs) are a clinically viable means to deliver RNA therapeutics. However, LNP-mediated mRNA delivery to brain tumors remains elusive. Over the past decade, numerous studies have shown that tumor cells communicate with each other via small extracellular vesicles, which are around 100 nm in diameter and consist of lipid bilayer membrane similar to synthetic lipidbased nanocarriers. We hypothesized that rationally designed LNPs based on extracellular vesicle mimicry would enable efficient delivery of RNA therapeutics to brain tumors without undue toxicity. We synthesized LNPs using four components similar to the formulation used in the mRNA COVID19 vaccines (Moderna and Pfizer): ionizable lipid, cholesterol, helper lipid and polyethylene glycol (PEG)-lipid. For the in vitro screen, we tested ten classes of helper lipids based on their abundance in extracellular vesicle membranes, commercial availability, and large-scale production feasibility while keeping rest of the LNP components unchanged. The transfection kinetics of GFP mRNA encapsulated in LNPs and doped with 16 mol% of helper lipids was tested using GL261, U87 and SIM-A9 cell lines. Several LNP formations resulted in stable transfection (upto 5 days) of GFP mRNA in all the cell lines tested in vitro. The successful LNP candidates (enabling >80% transfection efficacy) were then tested in vivo to deliver luciferase mRNA to brain tumors via intrathecal administration in a syngeneic glioblastoma (GBM) mouse model, which confirmed luciferase expression in brain tumors in the cortex. LNPs were then tested to deliver Cre recombinase mRNA in syngeneic GBM mouse model genetically modified to express tdTomato under LoxP marker cassette that enabled identification of LNP targeted cells. mRNA was successfully delivered to tumor cells (70-80% transfected) and a range of different cells in the tumor microenvironment, including tumor-associated macrophages (80-90% transfected), neurons (31- 40% transfected), neural stem cells (39-62% transfected), oligodendrocytes (70-80% transfected) and astrocytes (44-76% transfected). Then, LNP formulations were assessed for delivering Cas9 mRNA and CD81 sgRNA (model protein) in murine syngeneic GBM model to enable gene editing in brain tumor cells. Sanger sequencing showed that CRISPR-Cas9 editing was successful in ~94% of brain tumor cells in vivo. In conclusion, we have developed a library of safe LNPs that can transfect GBM cells in vivo with high efficacy. This technology can potentially be used to develop novel mRNA therapies for GBM by delivering single or multiple mRNAs and holds great potential as a tool to study brain tumor biology.
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Ionizable amino lipids are a major constituent of the lipid nanoparticles for delivering nucleic acid therapeutics (e.g., DLin-MC3-DMA in ONPATTRO , ALC-0315 in Comirnaty , SM-102 in Spikevax ). Scarcity of lipids that are suitable for cell therapy, vaccination, and gene therapies continue to be a problem in advancing many potential diagnostic/therapeutic/vaccine candidates to the clinic. Herein, we describe the development of novel ionizable lipids to be used as functional excipients for designing vehicles for nucleic acid therapeutics/vaccines in vivo or ex vivo use in cell therapy applications. We first studied the transfection efficiency (TE) of LNP-based mRNA formulations of these ionizable lipid candidates in primary human T cells and established a workflow for engineering of primary immune T cells. We then adapted this workflow towards bioengineering of CAR constructs to T cells towards non-viral CAR T therapy. Lipids were also tested in rodents for vaccine applications using self-amplifying RNA (saRNA) encoding various antigens. We have then evaluated various ionizable lipid candidates and their biodistribution along with the mRNA/DNA translation exploration using various LNP compositions. Further, using ionizable lipids from the library, we have shown gene editing of various targets in rodents. We believe that these studies will pave the path to the advancement in nucleic acid based therapeutics and vaccines, or cell gene therapy agents for early diagnosis and detection of cancer, and for targeted genomic medicines towards cancer treatment and diagnosis.
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Background & Aim: Gene therapies has become recognized for its remarkable clinical benefits in a variety of medical applications, in particular recent approval of an Ad vector-based COVID-19 vaccines have attracted recent global attention. Here, we present key considerations for GMP compliant process development for Coxsackie virus type B3 (CVB3), an oncolytic virus designed for clinical trial in triple-negative breast cancer. Methods, Results & Conclusion(s): CVB3 is a non-enveloped, linear single-strand RNA virus with a size of approximately 27-33 um in diameter. From the initial type using the zonal rotor centrifuge to the advanced type using the tangential flow filtration system and ion chromatograph, we considered the points of the design concept in constructing the manufacturing process. The final design system is constructed as a closed and single-use manufacturing system in which all processes from upstream large-scale cell culture to downstream target purification and concentration steps. In brief, HEK293 cell suspension extended in 3L serum-free medium infected with CVB3, up to 3.6 times 10 to 7 of TCID50 /mL before going to downstream steps, made total 150 mL of final products as 8.43 times 10 to 7 of TCID50/mL concentration. Although further quality control challenges remain that is removal of product-related impurities such as human cellular proteins and residual DNA/RNA to increase virus purity, this concept is effectively applicable even for other types of viruses as GMP manufacturing processes, and would be also important for technology transfer to future commercial production.Copyright © 2023 International Society for Cell & Gene Therapy
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Background & Aim: The pro-angiogenic, immunoregulatory and anti- inflammatory properties of MSCs are being exploited for the development of cellular therapies, including the treatment of graft versus host disease (GvHD), inflammatory bowel disease and COVID-19. SNBTS have developed a GMP process to bank umbilical cord MSCs (UC-MSCs) whereby we can reliably bank 100 vials of 10 million P2 UC-MSCs per cord. Each of these vials can be extensively expanded and stored for specific applications. The ultimate aim of the bank is for off-the-shelf clinical use, e.g., in GvHD or as an adjuvant therapy in Islet transplantations. Methods, Results & Conclusion(s): During process development, different basal media and supplements were screened for proliferation and MSC marker expression. Cells grown in promising media combinations were then tested for tri-lineage differentiation (identity), their chemokine/cytokine expression and T-cell inhibition (function) assessed. Medium selected for further GMP development and scale up was ultimately determined by all round performance and regulatory compliance. GMP-like UC-MSCs were shown to have immune-modulatory activity in T-cell proliferation assays at 4:1 or 16:1 ratios. Co-culture of UC-MSCs and freshly isolated leukocytes, +/- the immune activating agent LPS, show a dose dependent survival effect on leukocytes. In particular, neutrophils, which are normally very short lived in vitro demonstrated increased viability when co-cultured with UCMSCs. The survival effect was partially reproduced when UC-MSC were replaced with conditioned medium or cell lysate indicating the involvement of soluble factors. This improved neutrophil survival also correlates with results from leukocyte migration studies that demonstrate neutrophils to be the main cell type attracted to MSCs in in vitro and in vivo. Genetic modification of UC-MSC may improve their therapeutic potential. We have tested gene editing by CRISPR/Cas9 technology in primary UC-MSCS. The CXCL8 gene, highly expressed in UC-MSC, was targeted in isolates from several different donors with editing efficiencies of 78-96% observed. This translated to significant knockdown of CXCL8 protein levels in resting cells, however after stimulation levels of CXCL8 were found to be very similar in edited and non-edited UC-MSCs. This observation requires further study, but overall the results show the potential to generate future banks of primary UC-MSCS with genetically enhanced pro-angiogenic, immunoregulatory and/or anti-inflammatory activities.Copyright © 2023 International Society for Cell & Gene Therapy
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Background & Aim: The new UCOE models we have recently developed, tested on many cell groups (including mouse ES and human iPS cells) and human mAb recombinant production studies as well, shows a powerful resistance to DNA methylation- mediated silencing and provides a higher and stable transfection profile. By the urgent need of vaccine development for COVID-19 during the pandemic, in this study we aimed to produce a potential recombinant vaccine by using the new generation UCOEs models of our own design. Methods, Results & Conclusion(s): Existing new-generation UCOE models and standard plasmid vectors to be used as control group were provided. Then, the sequences related to the PCR method were amplified for sufficient stock generation and cloning experiments. Verification in the plasmid vector was carried out in gel electrophoresis. Transfection of 293T cells was performed with clone plasmids carrying antigen genes and plasmids carrying genetic information of lentivirus units for the production of lentiviral vectors. Afterwards, 293T cells produced lentiviral vectors carrying antigen genes. Harvesting of these vectors was carried out during 48th and 72nd hours. Afterwards, CHO cells were transduced with appropriate quantity of lentiviral vectors. Isolation and purification of targeted proteins from the relevant medium were performed by HPLC and Q-TOF methods. A part of the spike and nucleocapsid gene sequences of COVID-19 were firstly cloned into our UCOE models. These UCOEs plasmids were then transferred into 293T cells along with plasmids carrying the genes that will form the lentivirus vectors (LVs). After harvesting and calculation of LV vector titers, the cloned vectors were then transfected into the CHO cells which the targeted recombinant production of the antigen proteins will be carried out. Antigenic structures were then isolated from the culture medium of CHO cells in following days for confirmation. Using HPLC and qTOF mass spectrometer methods, these structures in the medium were confirmed to be the units of spike and nucleocapsid proteins of the COVID-19 virus. In order to produce large amount of the recombinant antigens, the culture was then carried out with bioreactors in liters. At the final stage, these recombinantly produced antigen proteins were tested on rats to measure their immunogenic responses, and the study recently been completed successfully as a potential recombinant vaccine against COVID-19.Copyright © 2023 International Society for Cell & Gene Therapy
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OBJECTIVE: To establish a rapid detection and genotyping method for SARS-CoV-2 Omicron BA.4/5 variants using CRISPPR-Cas12a gene editing technology. METHODS: We combined reverse transcription-polymerase chain reaction (RT-PCR) and CRISPR gene editing technology and designed a specific CRISPPR RNA (crRNA) with suboptimal protospacer adjacent motifs (PAM) for rapid detection and genotyping of SARS- CoV-2 Omicron BA.4/5 variants. The performance of this RT- PCR/ CRISPPR-Cas12a assay was evaluated using 43 clinical samples of patients infected by wild-type SARS-CoV-2 and the Alpha, Beta, Delta, Omicron BA. 1 and BA. 4/5 variants and 20 SARS- CoV- 2-negative clinical samples infected with 11 respiratory pathogens. With Sanger sequencing method as the gold standard, the specificity, sensitivity, concordance (Kappa) and area under the ROC curve (AUC) of RT-PCR/CRISPPR-Cas12a assay were calculated. RESULTS: This assay was capable of rapid and specific detection of SARS- CoV-2 Omicron BA.4/5 variant within 30 min with the lowest detection limit of 10 copies/µL, and no cross-reaction was observed in SARS-CoV-2-negative clinical samples infected with 11 common respiratory pathogens. The two Omicron BA.4/5 specific crRNAs (crRNA-1 and crRNA-2) allowed the assay to accurately distinguish Omicron BA.4/5 from BA.1 sublineage and other major SARS-CoV-2 variants of concern. For detection of SARS-CoV-2 Omicron BA.4/5 variants, the sensitivity of the established assay using crRNA-1 and crRNA-2 was 97.83% and 100% with specificity of 100% and AUC of 0.998 and 1.000, respectively, and their concordance rate with Sanger sequencing method was 92.83% and 96.41%, respectively. CONCLUSION: By combining RT-PCR and CRISPPR-Cas12a gene editing technology, we successfully developed a new method for rapid detection and identification of SARS-CoV-2 Omicron BA.4/5 variants with a high sensitivity, specificity and reproducibility, which allows rapid detection and genotyping of SARS- CoV-2 variants and monitoring of the emerging variants and their dissemination.
Subject(s)
COVID-19 , Humans , CRISPR-Cas Systems , Genotype , Reproducibility of Results , Reverse Transcriptase Polymerase Chain Reaction , SARS-CoV-2/genetics , RNA , COVID-19 TestingABSTRACT
Since 2009, the European Association for Predictive, Preventive and Personalised Medicine (EPMA, Brussels) promotes the paradigm change from reactive approach to predictive, preventive, and personalized medicine (PPPM/3PM) to protect individuals in sub-optimal health conditions from the health-to-disease transition, to increase life-quality of the affected patient cohorts improving, therefore, ethical standards and cost-efficacy of healthcare to great benefits of the society at large. The gene-editing technology utilizing CRISPR/Cas gene-editing approach has demonstrated its enormous value as a powerful tool in a broad spectrum of bio/medical research areas. Further, CRISPR/Cas gene-editing system is considered applicable to primary and secondary healthcare, in order to prevent disease spread and to treat clinically manifested disorders, involving diagnostics of SARS-Cov-2 infection and experimental treatment of COVID-19. Although the principle of the proposed gene editing is simple and elegant, there are a lot of technological challenges and ethical considerations to be solved prior to its broadly scaled clinical implementation. This article highlights technological innovation beyond the state of the art, exemplifies current achievements, discusses unsolved technological and ethical problems, and provides clinically relevant outlook in the framework of 3PM.
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In recent years, organoid technology has become one of the major technological breakthroughs in biomedical field. As miniature organs constructed by three-dimensional culture of tissue stem cells in vitro, organoids are highly consistent with the source tissues in terms of tissue structures, cell types and functions, which serve as an ideal model for biomedical basic research, drug research and development and clinical precision medicine, and show important potential value in regenerative medicine. Organ transplantation is one of the most effective approaches to treat organ failure. However, the source of donor organs is currently limited, which could not meet the patients' needs. Identifying suitable graft substitutes is the key to breaking through the predicament. Organoids could be derived from the autologous tissues of patients. Multiple studies have demonstrated that organoids possess potent transplantation and repairing capabilities and may effectively avert the risk of immune rejection and tumorigenicity, etc. In this article, the development process and main application directions of organoid technology were summarized, and the application prospect and challenges of organoids in organ transplantation were reviewed and predicted.Copyright © 2022 Journal of Zhongshan University. All right reserved.
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Background: Next-generation SARS-CoV-2 vaccines demonstrated that nanoparticle messenger ribonucleic acid (mRNA) delivery is effective and safe for in vivo delivery in humans. Current treatments for cystic fibrosis (CF) primarily focus on modulator drug therapies designed to correct malfunctioning CF transmembrane conductance regulator (CFTR) protein, but these modulators are ineffective for the 10% of people with CF with variants that do not allow protein production. Among these is the splice variant 3120 + 1G >A, the most common CF-causing mutation in native Africans. Gene editing would allow production of CFTR protein and enhancement of function using available CFTR modulators. We have demonstrated that electroporation of a modified CRISPR-Cas9 base editor to primary human bronchial epithelial cells carrying 3120 + 1G >A and F508del mutant alleles achieved 75% genome editing of the splice variant, resulting in approximately 40% wild-type (WT) CFTR function [1]. Here,we evaluate the effectiveness of several new nanoparticle formulations at delivering green fluorescent protein (GFP) mRNA to CF bronchial epithelial (CFBE41o-) cells. Using the optimal formulation,we then tested the efficacy correction of the 3120 + 1G >Avariant in a CFTR expression minigene (EMG) integrated into the genome of isogenic CFBE cells using mRNA and plasmid deoxyribonucleic acid (DNA) encoding adenine base editor (ABE) and guide (g)RNA. Method(s): GFP served as a reporter to evaluate transfection efficiency, cell viability, and mean fluorescence intensity (MFI) for three dosages (150, 75, 32.5 ng of mRNA), four polymer-to-mRNA to weight (w/w) ratios (60, 40, 30, 20), and four polymers (R, Y, G, B). 7-AAD served as a live/dead stain to quantify viability, with flow cytometry results analyzed using FlowJo software. CFBE cells stably expressing the 3120 + 1G >A EMG were transfected with the optimized nanoparticle formulation to deliver ABE and gRNA at two dosages (150, 75 ng) of mRNA and DNA. CFTR function in CFBE cellswas measured by short circuit current, forskolin stimulation, and inh-172 inhibition as a measure of editing efficiency. Result(s): Flow cytometry showed that polymer R achieved more than 85% GFP transfection, compared with a maximum of approximately 35% for the other three polymers at the maximum 150-ng dose, with approximately 80% viability normalized to untreated cells. In addition, polymer R achieved GFP MFI more than one order of magnitude as high as other formulations (~30 000 vs 2700 MFI) for the other three polymers at 150-ng dose and 40 w/w ratio. CFBE cells transfected with polymer R nanoparticles containing ABE and guide RNA at 75 ng and 150 ng showed mean CFTR function increase to 10 muA 6 (standard error of the mean [SEM] 1.1 muA) (~10% of WT) and 6.3 muA (SEM 0.9 muA) (~6% of WT), respectively. Greater toxicity at the higher dose could explain the larger increase in CFTR current at the lower dose. DNA-encoded ABE plasmid and gRNA showed a less robust increase in CFTR function (2.9 muA [SEM 0.4 muA] for 75-ng dose;3.0 muA [SEM 0.4 muA] for 150-ng dose), which was probably a result of the nanoparticle formulation being optimized for RNA instead of DNA cargo or the additional intracellular barriers that must be overcome for successful DNA delivery. Conclusion(s): We demonstrated that an optimized nanoparticle formulation containing ABE and gRNA can correct splicing of isogenic cells bearing the 3120 + 1G >A CFTR variant, resulting in recovery of CFTR function. In ongoing work, we are adapting these nanoparticles for RNA- and DNAencoded ABE and gRNA delivery to primary human bronchial epithelial cells.Copyright © 2022, European Cystic Fibrosis Society. All rights reserved
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The proceedings contain 206 papers. The topics discussed include: influenza: experiences from Kashmir;outbreaks of different viral etiologies amidst COVID-19 pandemic;development of a colorimetric isothermal (LAMP) assay for rapid detection of monkeypox virus;circulation of genetically diverse non-polio enteroviruses in respiratory samples during COVID-19 pandemic period (2021-22);evolutionary analysis of all eleven genes of species C rotaviruses circulating in humans and domestic animals;molecular characterization of dengue viruses circulating in Pune district, Maharashtra from 2009-2022;isolation and genomic characterization of cell fusing agent virus from aedes aegypti mosquitoes from Assam, India;structure-based identification and evaluation of antiviral activity of potent small molecule inhibitors targeting alphavirus RNA-dependent RNA polymerase;integration of HBV receptor NTCP into hepatoma cell using grnome editing;and hepatitis B virus genome targeting using CRISPR/Cas9based gene editing tool.
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RESEARCH QUESTION: Has acceptance of heritable genome editing (HGE) and whole genome sequencing for preimplantation genetic testing (PGT-WGS) of human embryos changed after the onset of COVID-19 among infertility patients? DESIGN: A written survey conducted between April and June 2018 and July and December 2021 among patients at a university-affiliated infertility practice. The questionnaire ascertained the acceptance of HGE for specific therapeutic or genetic 'enhancement' indications and of PGT-WGS to prevent adult disease. RESULTS: In 2021 and 2018, 172 patients and 469 patients (response rates: 90% and 91%, respectively) completed the questionnaire. In 2021, significantly more participants reported a positive attitude towards HGE, for therapeutic and enhancement indications. In 2021 compared with 2018, respondents were more likely to use HGE to have healthy children with their own gametes (85% versus 77%), to reduce disease risk for adult-onset polygenic disorders (78% versus 67%), to increase life expectancy (55% versus 40%), intelligence (34% versus 26%) and creativity (33% versus 24%). Fifteen per cent of the 2021 group reported a more positive attitude towards HGE because of COVID-19 and less than 1% a more negative attitude. In contrast, support for PGT-WGS was similar in 2021 and 2018. CONCLUSIONS: A significantly increased acceptance of HGE was observed, but not of PGT-WGS, after the onset of COVID-19. Although the pandemic may have contributed to this change, the exact reasons remain unknown and warrant further investigation. Whether increased acceptability of HGE may indicate an increase in acceptability of emerging biomedical technologies in general needs further investigation.
Subject(s)
COVID-19 , Infertility , Preimplantation Diagnosis , Pregnancy , Adult , Female , Child , Humans , Pandemics , Gene Editing , Genetic Testing , Infertility/genetics , Infertility/therapy , AneuploidyABSTRACT
In addition to its remarkable genome editing capability, the CRISPR-Cas system has proven to be very effective in many fields of application, including the biosensing of pathogenic infections, mutagenic defects, or early cancer diagnosis. Thanks to their many advantages in terms of simplicity, efficiency, and reduced time, several CRISPR-Cas systems have been described for the design of sensitive and selective analytical tools, paving the way for the development and further commercialization of next-generation diagnostics. However, CRISPR-Cas-based biosensors still need further research efforts to improve some drawbacks, such as the need for target amplification, low reproducibility, and lack of knowledge of exploited element robustness. This review aims to describe the latest trends in the design of CRISPR-Cas biosensing technologies to better highlight the insights of their advantages and to point out the limitations that still need to be overcome for their future market entry as medical diagnostics.Copyright © 2023 Elsevier B.V.
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Clustered regularly interspaced short palindromic repeats (CRISPR)-Cas systems, which are representative genome editing technologies, are classified into class 1 and class 2 in terms of evolutionary biology and are further classified into several subtypes. Class 2 CRISPR systems, including type II Cas9 and type V Cas12a, are the most commonly used for genome editing in eukaryotic cells, while type I CRISPR systems within Class 1 are also becoming available. Type I CRISPR recognizes longer target sequences than CRISPR-Cas9 and can induce large deletion mutations of several kilobases. These features demonstrate its potential as a novel and unique genome editing tool that can induce genetic disruption safely and reliably. Thus, it is expected to be utilized for gene therapy and industrial applications. Recently, the DNA cleavage mechanism of type I CRISPR has also revealed details from protein-complex analyses with X-ray crystallography, cryo-electron microscopy, and high-speed atomic force microscopy. The single-strand DNA trans-cleavage activity of type I CRISPR, called collateral activity, has broadened the potential application for CRISPR diagnostics, especially in the development of point-of-care testing methods for COVID-19. In this review, we present an overview of the type I CRISPR system, its application to genome editing, and genetic diagnosis using CRISPR-Cas3.Copyright © 2022
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Conditional control of RNA structure and function has emerged as an effective toolkit. Here, a strategy based on a one-step introduction of diacylation linkers and azide groups on the 2'-OH of RNA is advance. Selected from eight phosphine reagents, it is found that 2-(diphenylphosphino)ethylamine has excellent performance in reducing azides via a Staudinger reduction to obtain the original RNA. It is demonstrated that the enzymatic activities of Cas13 and Cas9 can be regulated by chemically modified guide RNAs, and further achieved ligand-induced gene editing in living cells by a controllable CRISPR/Cas9 system.
Subject(s)
CRISPR-Cas Systems , Gene Editing , CRISPR-Cas Systems/genetics , RNA, Guide, Kinetoplastida/geneticsABSTRACT
The prospect of gene therapy for inherited and acquired respiratory disease has energized the research community since the 1980s, with cystic fibrosis, as a monogenic disorder, driving early efforts to develop effective strategies. The fact that there are still no approved gene therapy products for the lung, despite many early phase clinical trials, illustrates the scale of the challenge: In the 1990s, first-generation non-viral and viral vector systems demonstrated proof-of-concept but low efficacy. Since then, there has been steady progress toward improved vectors with the capacity to overcome at least some of the formidable barriers presented by the lung. In addition, the inclusion of features such as codon optimization and promoters providing long-term expression have improved the expression characteristics of therapeutic transgenes. Early approaches were based on gene addition, where a new DNA copy of a gene is introduced to complement a genetic mutation: however, the advent of RNA-based products that can directly express a therapeutic protein or manipulate gene expression, together with the expanding range of tools for gene editing, has stimulated the development of alternative approaches. This review discusses the range of vector systems being evaluated for lung delivery; the variety of cargoes they deliver, including DNA, antisense oligonucleotides, messenger RNA (mRNA), small interfering RNA (siRNA), and peptide nucleic acids; and exemplifies progress in selected respiratory disease indications.
Subject(s)
Peptide Nucleic Acids , DNA , Gene Transfer Techniques , Genetic Therapy/methods , Genetic Vectors/genetics , Oligonucleotides, Antisense , RNA, Messenger , RNA, Small Interfering/geneticsABSTRACT
The prevalence of porcine enteric coronaviruses (PECs), including transmissible gastroenteritis virus (TGEV), swine acute diarrhea syndrome coronavirus (SADS-CoV), porcine delta coronavirus (PDCoV), and porcine epidemic diarrhea virus (PEDV), poses a serious threat to animal and public health. Here, we aimed to further optimize the porcine aminopeptidase N (pAPN) gene editing strategy to explore the balance between individual antiviral properties and the biological functions of pAPN in pigs. Finally, APN-chimeric gene-edited pigs were produced through a CRISPR/Cas9-mediated knock-in strategy. Further reproductive tests indicated that these gene-edited pigs exhibited normal pregnancy rates and viability. Notably, in vitro viral challenge assays further demonstrated that porcine kidney epithelial cells isolated from F1-generation gene-edited pigs could effectively inhibit TGEV infection. This study is the first to report the generation of APN-chimeric pigs, which may provide a natural host animal for characterizing PEC infection with APN and help in the development of better antiviral solutions. © 2022 Elsevier B.V.
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Clinically approved cell and gene therapies are opening up future possibilities to treat and prevent myriad diseases, which may include allergic diseases. In South Africa, this could help alleviate the high disease burden and economic cost of treating such diseases. However, even if viable gene-editing options to treat, cure and prevent allergic diseases become safe, effective and affordable for the South African market within the next few decades, the ethical implications and challenges of perceptions, regulation and oversight to ensure safety and equitable access remain. It would be important for all stakeholders involved, including the public and physicians, clinicians and ethicists on clinical and research ethics committees, to be informed about the possibilities, to engage in discussions with one another and to redress any gaps in knowledge. It would be especially important to determine whether cases for gene-editing aimed at allergy would be applied for therapeutic purposes or for enhancement. Much research and discussion remain to be embarked upon;however, it is imperative that research and engagement are expanded and prioritised.
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Viral diseases have emerged as a serious threat to humanity and as a leading cause of morbidity worldwide. Many viral diagnostic methods and antiviral therapies have been developed over time, but we are still a long way from treating certain infections caused by viruses. Acquired immunodeficiency syndrome (AIDS) is one of the challenges where current medical science advancements fall short. As a result, new diagnostic and treatment options are desperately needed. The CRISPR/Cas9 system has recently been proposed as a potential therapeutic approach for viral disease treatment. CRISPR/Cas9 is a specialised, effective, and adaptive gene-editing technique that can be used to modify, delete, or correct specific DNA sequences. It has evolved into an advanced, configurable nuclease-based single or multiple gene-editing tool with a wide range of applications. It is widely preferred simply because its operational procedures are simple, inexpensive, and extremely efficient. Exploration of infectious virus genomes is required for a comprehensive study of infectious viruses. Herein, we have discussed the historical timeline-based advancement of CRISPR, CRISPR/Cas9 as a gene-editing technology, the structure of CRISPR, and CRISPR as a diagnostic tool for studying emerging viral infections. Additionally, utilizing CRISPR/Cas9 technology to fight viral infections in plants, CRISPR-based diagnostics of viruses, pros, and cons, and bioethical issues of CRISPR/Cas9-based genomic modification are discussed.
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Rapid and accurate detection technologies are crucial for disease prevention and control. In particular, the COVID-19 pandemic has posed a great threat to our society, highlighting the importance of rapid and highly sensitive detection techniques. In recent years, CRISPR/Cas-based gene editing technique has brought revolutionary advances in biotechnology. Due to its fast, accurate, sensitive, and cost-effective characteristics, the CRISPR-based nucleic acid detection technology is revolutionizing molecular diagnosis. CRISPR-based diagnostics has been applied in many fields, such as detection of infectious diseases, genetic diseases, cancer mutation, and food safety. This review summarized the advances in CRISPR-based nucleic acid detection systems and its applications. Perspectives on intelligent diagnostics with CRISPR-based nucleic acid detection and artificial intelligence were also provided.